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Infinite Series
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2. Copyright © Cengage Learning. All rights reserved.
Power Series
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3. Objectives Understand the definition of a power series.
Find the radius and interval of convergence of a power series.
Determine the endpoint convergence of a power series.
Differentiate and integrate a power series.

4. Power Series

5. Power Series
An important function f(x) = ex can be represented exactly by an infinite series called a power series. For example, the power series representation for ex is
For each real number x, it can be shown that the infinite series on the right converges to the number ex.

6. Example 1 – Power Series The following power series is centered at 0.

7. Radius and Interval of Convergence

8. Radius and Interval of Convergence
A power series in x can be viewed as a function of x
where the domain of f is the set of all x for which the power series converges. Of course, every power series converges at its center c because

9. Radius and Interval of Convergence
So, c always lies in the domain of f. Theorem 9.20 (to follow) states that the domain of a power series can take three basic forms: a single point, an interval centered at c, or the entire real number line, as shown in Figure 9.17.
Figure 9.17

10. Radius and Interval of Convergence

11. Example 2 – Finding the Radius of Convergence
Find the radius of convergence of
Solution:
For x = 0, you obtain
For any fixed value of x such that |x| > 0, let un = n!xn.
Then

12. Example 2 – Solution
cont'd
Therefore, by the Ratio Test, the series diverges for |x| > 0 and converges only at its center, 0.
So, the radius of convergence is R = 0.

13. Endpoint Convergence

14. Endpoint Convergence
For a power series whose radius of convergence is a finite number R, Theorem 9.20 says nothing about the convergence at the endpoints of the interval of convergence.
Each endpoint must be tested separately for convergence or divergence.

15. Endpoint Convergence
As a result, the interval of convergence of a power series can take any one of the six forms shown in Figure 9.18.
Figure 9.18

16. Example 5 – Finding the Interval of Convergence
Find the interval of convergence of
Solution:
Letting un = xn/n produces

17. Example 5 – Solution
cont'd
So, by the Ratio Test, the radius of convergence is R = 1.
Moreover, because the series is centered at 0, it converges in the interval (–1, 1).
This interval, however, is not necessarily the interval of convergence.
To determine this, you must test for convergence at each endpoint.
When x = 1, you obtain the divergent harmonic series

18. Example 5 – Solution
cont'd
When x = –1, you obtain the convergent alternating harmonic series
So, the interval of convergence for the series is [–1, 1), as shown in Figure 9.19.
Figure 9.19

19. Differentiation and Integration of Power Series

20. Differentiation and Integration of Power Series

21. Example 8 – Intervals of Convergence for f(x), f'(x), and ∫f(x)dx
Consider the function given by
Find the interval of convergence for each of the following.
∫f(x)dx
f(x)
f'(x)

22. Example 8 – Solution By Theorem 9.21, you have and
cont'd
By Theorem 9.21, you have
and
By the Ratio Test, you can show that each series has a
radius of convergence of R = 1.
Considering the interval (–1, 1) you have the following.

23. Example 8(a) – Solution For ∫f(x)dx, the series
cont'd
For ∫f(x)dx, the series
converges for x = ±1, and its interval of convergence is
[–1, 1 ]. See Figure 9.21(a).
Figure 9.21(a)

24. Example 8(b) – Solution For f(x), the series
cont'd
For f(x), the series
converges for x = –1, and diverges for x = 1.
So, its interval of convergence is [–1, 1).
See Figure 9.21(b).
Figure 9.21(b)

25. Example 8(c) – Solution For f'(x), the series
cont'd
For f'(x), the series
diverges for x = ±1, and its interval of convergence is (–1, 1). See Figure 9.21(c).
Figure 9.21(c)